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RESEARCH ARTICLE
Human impact on the transport of terrigenous and anthropogenicelements to peri-alpine lakes (Switzerland) over the last decades
Florian Thevenon • Stefanie B. Wirth •
Marian Fujak • John Pote • Stephanie Girardclos
Received: 22 August 2012 / Accepted: 6 February 2013 / Published online: 22 February 2013
� The Author(s) 2013. This article is published with open access at Springerlink.com
Abstract Terrigenous (Sc, Fe, K, Mg, Al, Ti) and
anthropogenic (Pb and Cu) element fluxes were measured
in a new sediment core from Lake Biel (Switzerland) and
in previously well-documented cores from two upstream
lakes (Lake Brienz and Lake Thun). These three large peri-
alpine lakes are connected by the Aare River, which is the
main tributary to the High Rhine River. Major and trace
element analysis of the sediment cores by inductively
coupled plasma mass spectrometry (ICP-MS) shows that
the site of Lake Brienz receives three times more terrige-
nous elements than the two other studied sites, given by the
role of Lake Brienz as the first major sediment sink located
in the foothills of the Alps. Overall, the terrigenous fluxes
reconstructed at the three studied sites suggest that the
construction of sediment-trapping reservoirs during the
twentieth century noticeably decreased the riverine
suspended sediment load at a regional scale. In fact, the
extensive river damming that occurred in the upstream
watershed catchment (between ca. 1930 and 1950 and up to
2,300 m a.s.l.) and that significantly modified seasonal
suspended sediment loads and riverine water discharge
patterns to downstream lakes noticeably diminished the
long-range transport of (fine) terrigenous particles by the
Aare River. Concerning the transport of anthropogenic
pollutants, the lowest lead enrichment factors (EFs Pb)
were measured in the upstream course of the Aare River at
the site of Lake Brienz, whereas the metal pollution was
highest in downstream Lake Biel, with the maximum val-
ues measured between 1940 and 1970 (EF Pb [ 3). The
following recorded regional reduction in aquatic Pb pol-
lution started about 15 years before the actual introduction
of unleaded gasoline in 1985. Furthermore, the radiometric
dating of the sediment core from Lake Biel identifies three
events of hydrological transport of artificial radionuclides
released by the nuclear reactor of Muhleberg located at
more than 15 km upstream of Lake Biel for the time period
1970–2000.
Keywords Lake sediment � Terrigenous flux �Trace metals � Radionuclides � Human impact
Introduction
The high denudation rate (the sum of chemical weathering and
physical erosion) affecting the European Alps (up to
0.9 ± 0.3 mm/year in the Swiss Central Alps) is due to a high
relief, a steep topography and a high crustal thickness (Witt-
mann et al. 2007). The resulting particle transport is
particularly elevated in peri-alpine rivers with glacial catch-
ments, and the suspended particles primarily accumulate on
Electronic supplementary material The online version of thisarticle (doi:10.1007/s00027-013-0287-6) contains supplementarymaterial, which is available to authorized users.
F. Thevenon (&) � J. Pote
Institute F.-A. Forel, University of Geneva, Versoix, Switzerland
e-mail: [email protected]
S. B. Wirth
Geological Institute, ETH Zurich, Zurich, Switzerland
M. Fujak
Eawag, Swiss Federal Institute of Aquatic Science and
Technology, Dubendorf, Switzerland
S. Girardclos
Institut des Sciences de l’Environnement, University of Geneva,
Carouge, Switzerland
S. Girardclos
Dept of Geology and Paleontology, University of Geneva,
Geneva, Switzerland
Aquat Sci (2013) 75:413–424
DOI 10.1007/s00027-013-0287-6 Aquatic Sciences
123
the bottom of peri-alpine lakes, which have been acting as
sediment trap for upstream sediment erosion since the
deglaciation from the last glacial maximum (Bezinge et al.
1989; Hinderer 2001; Wessels 1998; Ivy-Ochs et al. 2004).
The quantification of sediment transport and terrigenous
fluxes at a river-basin scale therefore allows a better under-
standing of biogeochemical cycles at a regional scale
(Gaillardet et al. 1999; Millot et al. 2003; Pokrovsky et al.
2010). In addition, the analysis of the terrigenous particles
transported to peri-alpine lakes using sediment cores provides
an excellent opportunity for reconstructing the impacts of past
climate changes on the natural environment (Arnaud et al.
2005; Chapron et al. 2005; Girardclos et al. 2005). However,
little attention has been paid so far to the superimposed
anthropogenic influence, which substantially altered the sus-
pended sediment load of the main alpine rivers during the last
decades, principally due to particle retention in large reser-
voirs located behind hydropower dams (Loizeau and Dominik
2000; Syvitski et al. 2005; Wetter et al. 2011). In fact, the
riverine sediment transport in the European Alps, which is
primarily controlled by environmental factors (climate, veg-
etation cover and topography) influencing the rate and process
of weathering, has been significantly altered by the extensive
construction of reservoirs and hydroelectric dams that dras-
tically changed hydrological patterns and reduced suspended
sediment loads (Vorosmarty et al. 2003; Finger et al. 2006;
Thevenon et al. 2012). Therefore, attempts at understanding
present-day riverine discharge patterns based on river-borne
sediment material, or the reconstruction of past climate and
runoff variations based on the accumulation of lacustrine
sediments, should be applied with caution due to possible
human impact on the terrestrial elemental fluxes at the scale of
the drainage basin (Walling et al. 1998; Yang et al. 2005;
Wuest et al. 2007).
The studied system of the three lakes (Lake Brienz,
Lake Thun and Lake Biel) connected by one major river
(Aare River; Fig. 1) provides an excellent opportunity to
evaluate the impact of anthropogenic changes on element
fluxes through time. Indeed, the numerous hydropower
dams constructed upstream of Lake Brienz in the high-
alpine Grimsel area (up to 2,300 m a.s.l; Fig. 1) have
strikingly altered the seasonality of the river flow (shift of
the particle input from summer to winter) and have con-
siderably reduced the overall particle input from upstream
glaciers to Lake Brienz (Wuest et al. 2007). In addition to
these hydropower operations, the Aare River, which is the
main water supplier of the High Rhine River, was redi-
rected into Lake Biel in 1878 and has been regulated by the
Hagneck hydroelectric dam since 1900, in an effort to
prevent flooding of the nearby area called ‘‘Seeland’’
(Fig. 1). Finally, precipitation and stream-flow discharge
have been monitored for about 100 years in this region
(FOEN 2010; MeteoSwiss 2012) and therefore offer a
comprehensive dataset to compare historical climate and
human-induced hydrological changes with the recon-
structed changes in terrigenous sediment transport to peri-
alpine lakes.
The quantification of trace elements continuously
accumulating in the sediments at the bottoms of peri-alpine
lakes can be used to evaluate the modern pollution level as
well as to assess the temporal evolution of the water pol-
lution and its relation with (past) human activities
(Thevenon et al. 2011a; Thevenon and Pote 2012). Indeed,
the enrichment of trace metals in lacustrine sedimentary
archives gives access to the history of anthropogenic pol-
lutant input, and provides the possibility to evaluate the
recent metal contamination in comparison to the natural (or
pre-historic) level (Eades et al. 2002; Thevenon et al.
2011b). In the absence of long-term environmental records
that could provide pre-anthropogenic levels of pollutants
(i.e. natural background levels), the enrichment of trace
metals can be expressed relative to the lowest values in the
record, which are generally found in the oldest sections of
the analysed sediment records (Shotyk et al. 1998; Arnaud
et al. 2004; Thevenon et al. 2011b).
As a prerequisite of such a sediment-based environ-
mental reconstruction, well-dated sediment records are
demanded. Additionally to historical events, activity pro-
files of 137Cs and 210Pb radionuclides provide a valuable
dating tool for the 20th century and thus allow for the
calculation of element fluxes and the comparison of sedi-
ment records from different sites. Such a radiocesium
profile of sediment cores from Lake Biel (Switzerland,
Fig. 1) revealed anomalous 137Cs peaks dated to 1977 and
1982 that were caused by radionuclide discharges from the
upstream Muhleberg Nuclear Power Plant (NPP) (Albrecht
et al. 1998). The contamination of fluvial waters by liquid
releases from Swiss and French nuclear installations and
the long-term retention of long-lived radionuclides have
also been evidenced in surface and overbank sediments
from some of the major European rivers (e.g. Rhine, Rhone
and Moselle Rivers) (Mundschenk 1992, 1996; Provansal
et al. 2012; Ferrand et al. 2012). However, despite major
concerns for human health and the environment, continu-
ous and well-dated sedimentary records reconstructing the
historical deposition of anthropogenic radionuclides
released by the nuclear industry are still scarce.
Materials and methods
Study sites
The basic parameters of the tree studied lakes are sum-
marized in Table 1 and described in the presentation of the
lakes below.
414 F. Thevenon et al.
123
Lake Brienz
Lake Brienz lies at an altitude of 566 m a.s.l. in a frontal
range valley of the Swiss Alps. The Lake Brienz catch-
ment area covers 1,140 km2 and is situated in a partially
glaciated (*19 % of total area) mountainous environment
with 50 % of its surface lying above 2,000 m a.s.l. The
lake has a surface area of 29.8 km2, a volume of 5.17 km3
and a maximum depth of 261 m. It is holomictic and
ultra-oligotrophic with almost exclusively allochthonous
clastic input. The water residence time is 2.7 years
(Liechti 1994).
The Aare and the Lutschine rivers are the major water
and sediment suppliers to Lake Brienz. Although the dis-
charge of the heavily dammed Aare River (gauging station
in Brienzwiler) is still nearly twice as high as that of the
Lutschine River (not dammed; gauging station in Gsteig)
(Figs. 1, 4), the annual sediment loads are almost equal in
both rivers. However, the annual particle input to the
uppermost part of the lake’s water column is dominated by
material from the Aare River (92.8 kt/year compared with
64.7 kt/year from the Lutschine River) (Finger et al. 2006).
The total annual sediment input into Lake Brienz lies in the
range of 250–350 kt (average 302 kt) and has decreased by
approximately 232 kt/year due to sedimentation in the
reservoirs Grimselsee, Raterichsbodensee and Oberaarsee
(Anselmetti et al. 2007) (Fig. 1) (for details about the
construction of the hydroelectric dams in the Grimsel
region see Supplementary Data, Table S1).
The sediments of Lake Brienz mainly consist of fine-
grained (clayey silt) material that is intercalated by sandy
layers. The most conspicuous deposit present in the sedi-
ment record during the investigated time period is a large
subaquatic mass movement that was triggered at the Aare
delta in 1996 and eroded up to 20 cm of sediment in the
deep basin (Girardclos et al. 2007).
Fig. 1 Map of the studied area
presenting the old and new
courses of the Kander and Aare
rivers, the location of the dams
mentioned in the text (markedby black rectangles), the
location of the sediment cores
(indicated by red dots) retrieved
from Lake Biel (BIE10-3; this
study), Brienz (BR03-10;
Anselmetti et al. 2007) and
Thun (THU07-06; Wirth et al.
2011), as well as the location of
the Muhleberg nuclear power
plant and the gauging stations
(grey dots) mentioned in the
text. Upper right insert Map of
Switzerland indicating mean
annual precipitation
(1961–1990; MeteoSwiss 2012),
the studied area (white dashedsquare) and the catchment area
of Lake Biel (non-shaded area)
Table 1 Physical characteristics of Lake Brienz, Thun and Biel (Liechti 1994)
Lake Brienz Lake Thun Lake Biel
Surface area 29.8 km2 48.4 km2 39.3 km2
Surface elevation 566 m a.s.l. 558 m a.s.l. 429 m a.s.l.
Maximum water depth 261 m 217 m 74 m
Water volume 5.17 km3 6.44 km3 1.24 km3
Water residence time 2.7 years 684 days 58 days
Catchment area 1,140 km2 2,451 km2 8,305 km2
Present trophic state Ultra-oligotrophic Oligo-mesotrophic Mesotrophic
Lake type Holomictic Holomictic Holomictic
Main tributaries Aare and Lutschine Kander and Aare Aare
Human impact on the transport 415
123
Lake Thun
Lake Thun is situated downstream of Lake Brienz along
the Aare River course (Fig. 1). It has a surface area of
48.4 km2, a volume of 6.44 km3, a maximum depth of
217 m and is situated at an altitude of 558 m a.s.l. It is
holomictic and oligo-mesotrophic and has a residence time
of 684 days (Liechti 1994). Its main tributaries, the Kander
and Aare rivers, are responsible for 90 % of the water
supply. The Aare River, which first flows through deep
Lake Brienz (Fig. 1), arrives in Lake Thun almost free of
coarse particles (Sturm and Matter 1972). In contrast, the
Kander River, which was deviated into Lake Thun in 1714
(Fig. 1), is rich in clastic sediment load. Its deviation
therefore increased the lake’s sediment input by a factor of
two or three between 1714 and 1840 before river-bed
erosion in the Kander catchment ceased and the sedimen-
tation rates re-adjusted to almost pre-Kander conditions
(Wirth et al. 2011). At present, 85 % of the sediment input
to Lake Thun is supplied by the Kander River (Sturm and
Matter 1972).
Lake Biel
Lake Biel is situated downstream of Lake Brienz and
Lake Thun (Fig. 1). It has a surface area of 39.3 km2, a
volume of 1.24 km3, a maximum depth of 74 m and lies
at an altitude of 429 m a.s.l. Lake Biel is subdivided into
two basins (north and south) that merge in the eastern
part of the lake. It is holomictic and has changed from
mesotrophic in the 1950s to eutrophic in the 1990s, with
a hyper-eutrophic peak in the 1970s (Liechti 1994). The
Aare River is the only tributary for the southern basin
and the main water supplier of Lake Biel. It delivers
80 % of the water and 90 % of the allochthonous par-
ticulate matter to the lake. This sediment load largely
derives from the Sarine River, a tributary to the Aare
River downstream of the city of Bern (Fig. 1), as the
Aare River first flows through the large decantation
basins of Lake Brienz and Lake Thun acting as efficient
sediment traps. The Aare River has only been flowing
into Lake Biel since 1878 when the river was deviated
by the Hagneck Channel into the lake in order to control
devastating floods in the Seeland area (Fig. 1). The
Hagneck Channel was widened in 1878 but the river
continued to intensely erode the river-bed and new sta-
bilisation constructions were built between 1887 and
1900. With the completion of these additional construc-
tions the Hagneck hydroelectric dam was finally
inaugurated in 1900 (Nast 2006). The Aare River devi-
ation increased the catchment area of Lake Biel by a
factor of four, leading to an increase in the mean water
input from 55 to 240 m3/s, which in turn reduced the
mean residence time from 253 to 58 days (Liechti 1994).
In addition to this major deviation, the regional river
management program called ‘Jura waters correction’ also
included the canalization of the naturally inflowing small
rivers (Broye and Thielle) as well as a *2.5 m lowering
of the mean lake level of Lake Biel in order to drain the
surrounding wetland areas.
Reservoirs built along the Aare River
Upstream of Lake Brienz, the flow of the Aare River is
affected by seven reservoirs associated with six hydro-
power units. 68 % of the Aare River runoff is collected
in this reservoir-lake system (between 862 and 2,365 m
a.s.l) and is reinjected into the Aare River at an altitude
of 620 m a.s.l (Fig. 1) (Finger et al. 2006). It has been
demonstrated that the construction of hydropower dams
upstream of Lake Brienz in the high-alpine area of the
Grimsel Pass (Grimsel dam at 1909 m a.s.l built in
1929, Raterichsboden dam at 1,767 m a.s.l in 1950, and
Oberaar dam at 2,303 m a.s.l. in 1953; Fig. 1) has
drastically diminished particle fluxes from the upstream
glaciers to Lake Brienz. Specifically, hydropower oper-
ations have induced a shift of the particle inputs from
summer to winter and have minimized peak discharges
(i.e. summer high-flow events) as well as the intrusion
depth of the Aare River waters in Lake Brienz (Finger
et al. 2006; Wuest et al. 2007). Anselmetti et al. (2007)
furthermore estimated that only 39 kt/year of fine-
grained (\4 lm) sediment (of the total 271 kt/year of
solid particles that entered the Grimsel reservoirs on
average during the last 71 years) were transported
downstream to Lake Brienz, while 232 kt/year of mostly
coarse particles were retained. Therefore, the total sed-
iment input of the Aare River into Lake Brienz was
reduced by two-thirds. Further details about the con-
struction of the main dams in the Grimsel area are
provided in the Supplementary Data (Table S1) of this
study.
Concerning the Sarine River, which is a major tributary
of the Aare River downstream of the city of Bern, the most
important hydrological change over the past century was
the construction of the Rossens dam that was finished in
1948. Following the completion, it took 4 months for the
river to form the second largest artificial reservoir in
Switzerland (200 millions m3) by filling Lake Gruyere
(Fig. 1). Since then, the Sarine river discharge pattern has
been heavily influenced by the hydroelectricity production,
which maintains the downstream water discharge almost
constant, excluding times of strong flood events (i.e. in
1999, 2005 and 2006).
416 F. Thevenon et al.
123
Methodology
Sediment coring, logging and sampling
In 2003, a 77-cm-long gravity core (BR03-10) was col-
lected from central Lake Brienz (46�4401700N, 7�5805400E)
at 260 m water depth. This core was initially analysed to
reconstruct the sediment input to Lake Brienz (Anselmetti
et al. 2007).
In 2007, a 98-cm-long gravity core (THU07-06) was
also collected from central Lake Thun (46�4003600N,
7�4503700E) at 212 m water depth, in an effort to evaluate
changes in sediment input to Lake Thun following the re-
routing of the Kander River (Wirth et al. 2011).
In 2010, a 119.5-cm-long gravity core (BIE10-3) was
collected from the southern basin of Lake Biel (47�301400N,
7�80800E) at 52 m water depth.
After their collection, gamma-ray attenuation bulk
density was measured on whole-round cores using a
GEOTEK multi-sensor core logger. Afterwards, the cores
were opened, photographed and sliced into 1 cm thick
sections. These sediment samples were frozen, freeze-dried
and ground into a fine homogeneous powder for chemical
analysis. Water content was measured by weighing indi-
vidual samples before and after freeze-drying.
Radionuclide activities
The 137Cs activities of the cores from Lake Brienz, Lake
Thun and Lake Biel were measured following the same
procedure at Eawag (Dubendorf, Switzerland). Radionu-
clide activities (226Ra t1/2 = 1,601 years; 241Am t1/2 =
432 years; 137Cs t1/2 = 30.2 years; 210Pb t1/2 = 22.3 years
and 60Co t1/2 = 5.3 years) were determined in Bq/kg (dry
weight) by c-ray spectroscopy on high-purity germanium
(Ge) well detectors. Geometry correction and calibration
were based on standard solutions from 1 to 10 mL, which
were adapted to sample masses ranging between 0.5 and
1 g dry weight.
Chemical treatment and ICP-MS measurements
Around 2–3 mg of sediment powder was completely
digested using pure acids in Teflon bombs and a glass
ceramic hotplate. The procedure involves three heating
steps with (1) 0.5 ml HNO3 (suprapur�, 65 %), (2) a
mixture of 0.3 ml of HClO4 (suprapur�, 70 %) with 0.3 ml
HF (suprapur�, 40 %), and (3) one additional treatment
with 0.3 ml of HNO3 (suprapur�, 65 %). The samples were
evaporated between each step of the procedure and finally
diluted to 10 ml with 1 % HNO3 solution for chemical
analysis.
The concentrations of major and trace elements
[including scandium (Sc), iron (Fe), potassium (K), mag-
nesium (Mg), aluminium (Al), titanium (Ti), copper (Cu),
and lead (Pb)] were measured using a quadrupole-based
inductively coupled plasma-mass spectrometer (ICP-MS,
model 7700 series, Agilent). Multi-element standard solu-
tions at different concentrations (0, 0.02, 1, 5, 20, 100 and
200 ppb) were used for calibration. Standard deviations of
four replicate measurements (done for each element) were
below 10 %, and chemical blanks for the procedure were
less than 5 % of the sample signal. Concentrations of the
different elements (given as lg/g or mg/g dry weight) were
converted to element fluxes in order to correct for varying
sedimentation rates when comparing the records from the
three lakes. Element fluxes were calculated using the fol-
lowing equation:
Element flux (lg or mg/cm2/year) = Element concen-
tration (lg/g or mg/g) 9 Sedimentation rate (cm/year) 9
Density (g/cm3)
In order to decipher the anthropogenic contribution to
the trace-metal content, we calculated the enrichment
factors (EFs) for Pb concentrations using the following
equation:
EF = (Pb concentration in sample/Sc concentration in
sample)/(the lowest Pb/Sc ratio of each record)
The conservative element scandium (Sc) was chosen
because it occurs in the same concentration range as Pb in
natural (uncontaminated) sediments and is unaffected by
human activities.
Results and discussion
Age models for Lake Brienz and Lake Thun
The age models for the records of Lake Brienz (BR03-10)
and Lake Thun (THU07-06) are based on core-to-core
correlations with previously well-dated sediment cores
from these two lakes (see Supplementary Data of this
study, Figs. S1 and S2). The age-depth relation is estab-
lished using the 137Cs markers of 1951 (zero level), 1963
and 1986, as well as event-layer stratigraphies from flood
and mass movement deposits. Details about the dating of
the cores from Lake Brienz and Lake Thun are described in
Anselmetti et al. (2007) and Wirth et al. (2011),
respectively.
Age model for Lake Biel
The age model for the Lake Biel core (BIE10-3) is well
constrained by radionuclide activity profiles of 137Cs, 60Co,210Pb, 226Ra and 241Am as well as by two additional
tie points, which are the coring year (2010) and the
Human impact on the transport 417
123
completion of the Hagneck hydroelectric dam (1900;
Fig. 2). Using the CFCS (constant flux constant sedimen-
tation) model (Krishnaswamy et al. 1971), the 210Pb age
model is constrained by the best-fitted (R2 = 0.91) linear
slope of excess 210Pb (obtained by subtracting the 226Ra
activity to the 210Pb activity), which could be measured
down to 63.5 cm core depth (i.e. 1932) and provides a
mean sedimentation rate of 0.86 cm/year. This sedimen-
tation rate was applied to the lower part of the core by
extrapolation, resulting in an age of 1900 AD at 94.5 cm
core depth. This stratigraphic level coincides with con-
spicuous changes in lithology and magnetic susceptibility
(Fig. S3), which are interpreted as decreased clastic input
caused by sediment retention due the upstream Hagneck
hydroelectric dam. However, as river-bed erosion by the
Aare River only stabilized with the completion of the
Hagneck dam in 1900 (Nast 2006), the sedimentation rate
is likely enhanced for the period 1878–1900. Due to this
uncertainty, the age model was not extended beyond 1900
(i.e. 94.5 cm). For the period 1951–2010, the age model
was verified using the 137Cs activity peaks of 1986 (1985
with 210Pb age model) and 1963 (1962 with 210Pb age
model) generated by the Chernobyl accident and the global
maximum radionuclide fallout due to atmospheric tests of
nuclear weapons, respectively. In addition, the beginning
of 137Cs emission in 1951 (i.e. end of 137Cs zero activity) is
also used as a marker horizon (1950 with 210Pb age model,
Fig. 2). Furthermore, the 241Am activity peak at 41.5 cm
depth confirms the 1963 137Cs peak due to atmospheric
fallout. Overall, the 210Pb- and 137Cs age models differ
only by about 1 year, which is likely due to measurement/
sampling uncertainties and model used.
Impact of manmade reservoirs on element fluxes
Instrumental precipitation records from different monitor-
ing stations in Central Switzerland (Begert et al. 2005)
present strikingly similar variations but nonetheless indi-
cate that more precipitation falls in mountainous areas
(Engelberg and Chateau d’Oex: 1,200–1,700 mm/year)
than on the Swiss Plateau (Bern: *1,000 mm/year)
(Fig. 4). This pattern is due to the altitude effect of pre-
cipitation (*0.7 mm/m in altitude in the northern part of
the Alps; Schadler and Weingartner 2002), which is
strongly influencing the distribution of mean annual pre-
cipitation in Switzerland (Fig. 1). Despite considerable
seasonal and topographic effects, the analysis of meteoro-
logical data sets has shown that the annual precipitation
amounts in Switzerland during the twentieth century
slightly increased in most sub-regions and for all seasons
with the exception of summer (Widmann and Schar 1997).
Regarding the here used meteorological stations, a slight
long-term increase in total annual precipitation is observed
for the station of Chateau d’Oex, while the two other
precipitation series (Engelberg and Bern) remain relatively
constant over the last century (Fig. 4).
The discharge records of the Lutschine River (number 5
in Fig. 4), which is an Alpine torrent largely unaffected by
human activities, and of the Aare River in Thun and Bern
(number 3 and 2 in Fig. 4) both show a good consistency
with the temporal trends of the precipitations series (FOEN
2010). However, these patterns strongly contrast to the
discharge of the Aare River measured in the upper part of
its watershed (gauging station in Brienzwiler, number 4 in
Fig. 4), for which a decreasing trend is observed between
1930 and 1970, occurring synchronously with the con-
struction of the hydropower reservoirs upstream of Lake
Brienz (number 12 in Fig. 4). Synchronously with the
extensive construction of dams in Switzerland, abrupt
drops are also recorded in the discharge pattern of the
Sarine River in Fribourg (number 1 in Fig. 4). Thereby, the
most conspicuous decrease in the Sarine River discharge
occurred after the construction of the Rossens dam in 1948
(number 13 in Fig. 4). Furthermore, the intense contem-
poraneous economic development as well as the
availability of infrastructures for water storage and water
delivery in these areas certainly fostered water withdrawal
for human uses (agriculture, industry and municipal use).
This may be especially important in the Rossens area and
in the vicinity of Lake Biel, where agriculture is more
important than in the upstream course of the Aare River.
It has recently been demonstrated that the river-trans-
ported sediment load into Lake Brienz is strongly
dependent on the peaks in the discharge regime and that
hydropower damming has drastically diminished particle
fluxes and minimized (short-term) peak discharges (Finger
et al. 2006; Bonalumi et al. 2011). Hence, hydropower
operations in the Grimsel area significantly modified sus-
pended particle loads (and seasonal water discharge) to
Lake Brienz (Finger et al. 2006). An additional study
conducted on the sedimentation of the fine particle fraction
from the water column in the two high-altitude reservoirs
Oberaarsee and Grimselsee (Fig. 1) that have been used for
pump-storage operations since 1980 demonstrated that
pump-storage operations have not only strongly modified
the downstream but also the overall sedimentation pro-
cesses (Bonalumi et al. 2011). Before the construction of
the reservoirs particle input to Lake Biel mainly happened
during snowmelt in late spring/early summer and during
extreme runoff events in summer (Finger et al. 2006).
However, upstream hydropower operations have shifted
the main part of the sediment input from summer to winter.
The fluxes of terrigenous elements (Sc, Ti, Mg, Fe, K
and Al) transported to the coring sites of Lake Brienz, Lake
Thun, and Lake Biel do not follow the precipitation pattern
of the area, strongly suggesting a catchment scale impact of
418 F. Thevenon et al.
123
the numerous water reservoirs constructed in the upstream
part of the catchment area since about 1930 (Fig. 3). For
example, the Ti flux record of Lake Biel shows a strong
decrease from values ranging around 4 mg/cm2/year to
values around 3 mg/cm2/year after ca. 1950 (Fig. 4), sug-
gesting a reduction of the terrigenous flux of *25 %
during the second part of the twentieth century. A similar
reduction in the transportation of Ti is also observed in
Lake Brienz between 1950 and 1970 (Fig. 4). Although an
additional effect of artificial water withdrawal (especially
for agriculture) cannot be ruled out, our sedimentary
records of terrigenous material fluxes from Lake Biel and
Lake Brienz indicate that the shift of the main runoff from
summer to winter due to the hydropower damming com-
bined to the retention of suspended particles in the
reservoirs (see previous paragraph), significantly reduced
the riverine sediment load of the Aare River. A similar
reduction in the recent transport of terrigenous elements
has been reported in other large and deep peri-alpine lakes.
Before the beginning of massive land-use changes in the
late-nineteenth century, the crustal element concentrations
in the sediments of Lake Lucerne that are associated with
the silicate-clay fraction were primarily influenced by cli-
mate-induced hydrological changes (Thevenon et al. 2012).
By contrast, the lower Ti input also measured in the
deepest part of Lake Geneva during the twentieth century
(Fig. S5; details in Thevenon et al. 2011a) indicates
reduced terrigenous sediment transport due to lower sum-
mer Rhone River flows and increased sediment entrapment
in the numerous reservoirs built along the upstream Rhone
River course (Loizeau et al. 1997). These studies demon-
strate that the extensive construction of water reservoirs
during the middle of the twentieth century in Switzerland
significantly reduced terrigenous fluxes to major alpine
rivers and to the large and deep peri-alpine lakes.
The three times higher flux of terrigenous elements into
upstream Lake Brienz compared to downstream Lake Thun
and Lake Biel can be easily explained by more intense
weathering and hydrological processes in its glaciated
mountainous catchment (resulting in a higher flux of ter-
rigenous sediment transported by the Lutschine and Aare
rivers) and also by the fact that Lake Brienz constitutes the
first large sediment sink of the Aare River (Girardclos et al.
2007) (Fig. 3 and S5).
Importantly, turbidites related to large mass movements
in Lake Brienz (details in Girardclos et al. 2007) were not
reported in Figs. 3 and 4. Apparently, such events strongly
enhance elemental fluxes because of a sudden increase
in sedimentation rate and terrigenous element input
(Fig. S5). However, these mass movement deposits represent
Fig. 2 Left Radionuclide activities of the Lake Biel sediment core
(BIE10-3). Excess 210Pb activity (226Ra activity subtracted) with
horizontal error bars expressed as 95 % confidence levels and the
regression line (R2 = 0.91) showing a constant sedimentation rate
(0.86 cm/year) down to 63.5 cm (1937). Activities of 137Cs, 241Am,60Co and 60Co were decay corrected with peak emission sources (the
data below the detection limit for 60Co are not represented). RightAge-depth model of the sediment record based on excess 210Pb
showing the chronological markers derived from radionuclides
activities (left part). The coring year (2010) and the Hagneck
hydroelectric dam inauguration year (1900) have been added (Fig. S3
for details on core interpretation)
Human impact on the transport 419
123
material redeposited within the lake basin and therefore do
not reflect riverine sediment input. In contrast, two small
turbidites triggered by flood events detected in the lower
and upper parts of the sediment core of Lake Thun reflect
real short-term increases of elements fluxes (Figs. 3 and 4)
(see Wirth et al. 2011 for details about these turbidites).
Element fluxes for tracking anthropogenic pollution
In contrast to the natural elemental fluxes, differences
among the three lakes are observed in the occurrence of
anthropogenically-derived elements. Indeed, Pb and Cu
fluxes into Lake Biel during the middle of the 20th century
strongly differ from the above-presented pattern of the
natural trace elements (Fig. 3 and S4). This is explained by
a higher anthropogenic contribution to heavy metal influx
in the downstream reaches of the Aare River (EF Pb,
Fig. 4). The natural flux of Pb into Lake Brienz (80 lg/
cm2/year) is two times higher than to Lake Thun
(40 lg/cm2/year) and four times larger than to Lake Biel
(20 lg/cm2/year) (Fig. 3). The Lake Brienz record does
not give evidence for anthropogenic lead deposition,
whereas a moderate enrichment of Pb ([1.5) is detected in
Lake Thun. In contrast, the Lake Biel sediment record is
characterized by a strong enrichment of Pb, which is
similar as in the deepest part of Lake Geneva following the
industrial revolution (Thevenon et al. 2011a; Fig. 4). One
must note that the lowest values found in the records might
still include some amounts of human-induced trace metals
because anthropogenic trace-metal pollution in the large
Swiss lakes started to increase following the industrial
revolution in Europe in ca. 1850 (Thevenon et al. 2011a,
2011b; Thevenon and Pote 2012). However, as a result of
the very high dilution by the Rhone River (mean discharge
Fig. 3 Trace element fluxes of Lake Biel, Lake Thun and Lake
Brienz as a function of age (calendar years). A large turbidite layer
deposited in 1996 interrupts the sedimentary record and generates a
hiatus of 17 ± 1 years in core BR03-10 (details in Girardclos et al.
2007). Note the log scale for Fe, K and Al
420 F. Thevenon et al.
123
of 654 m3/s over the last 56 years; FOEN 2010) for Lake
Geneva and by the Aare River (mean discharge of
717 m3/s over the last 27 years; FOEN 2010) for Lake
Biel, EF Pb remains relatively low in both lake sediments
shortly after the industrial revolution whereas maximum
values are reached between 1950 and 1970 (EF Pb [ 3;
Fig. 4). Since 1970, anthropogenic Pb has decreased to the
level of the late 19th century in Lake Thun and Lake Biel
(Fig. 4). Interestingly, this long-term reduction in aquatic
Pb pollution started about 15 years before the introduction
of unleaded gasoline and synchronously with the large
peri-alpine Lake Lucerne and Lake Geneva. As demon-
strated by the isotope systematic of Pb, which was used to
determine the origin of Pb (Monna et al. 1999; Thevenon
et al. 2011a), the reduction in Pb input into these lakes
primarily resulted from an increase in the number of
sewage plants and thus the improved treatment of indus-
trial (and domestic) wastewaters in the largest cities of
Switzerland.
Although the maximum anthropogenic Pb input to Lake
Biel occurred between 1950 and 1970, i.e. during the time
period when leaded gasoline was used in Switzerland
(between 1947 and 1985), the striking similarity between the
Pb and Cu records (Fig. 3) suggests the same origin and
transport pathway for these two elements rather than the use
of leaded gasoline as dominant source of lead in Lake Biel
during this period. This result is consistent with (1) the
sedimentary records from other low- and high-altitude lakes
Fig. 4 Instrumental records of annual precipitation as 3 year running
average (numbers 2, 6 and 7) (Begert et al. 2005) and of annual river
discharge as 5 year running average (FOEN, 2010) with locations of
gauging stations (1 to 5) reported on the inserted map. Beneath follow
the dates of dam constructions upstream of Lake Biel (12 and 13) as
well as Ti fluxes and Pb enrichment factors (EF Pb) for Lake Biel (8),
Lake Thun (9) and Lake Brienz (10). EF Pb from Lake Geneva (11) is
reported for comparison
Human impact on the transport 421
123
recently studied in Switzerland, indicating a similar pattern
of Pb enrichment and of other anthropogenic metals (e.g. Hg,
Cu, Zn, Mn) (Thevenon et al. 2011a, 2011b, 2013), and with
(2) peat bog records of lead pollution in Switzerland, indi-
cating a maximum extent of atmospheric contamination
(primarily supplied by coal burning) in Europe in 1954,
which predates the maximum impact of Pb emissions from
the use of leaded gasoline (Shotyk et al. 2002). Similarly to
the large and deep peri-alpine Lake Constance (NE Swit-
zerland), the apparent absence of a significant gasoline Pb
peak in Lake Biel (and in the other peri-alpine lakes men-
tioned before) during the 1970s and 1980s could therefore be
due to a compensation of the enhanced aeolian Pb flux
(gasoline Pb) by a much lower release of fluvial Pb (building
of sewage plants) after 1960 (Kober et al. 1999). The sedi-
mentary records from the large peri-alpine lakes therefore
exclude alkyl-lead added to petrol as the major source of
(aquatic) Pb pollution, and rather point at an overall metal
pollution due to increasing urbanization and industrializa-
tion processes (waste incineration, metal smelting processes
and fossil fuel combustion) until the 1970s. Increased
emission controls, becoming effective in the late 1970s,
reduced atmospheric (metal) pollution and implemented
wastewater treatment plants to reduce industrial (and
domestic) aquatic metal pollution.
Evidence for contamination by the nuclear power plant
Additionally to the three 137Cs markers generally used for
dating (1951, 1963 and 1986) European sediment records,
the Lake Biel sediment core (BIE10-3) revealed two
additional 137Cs activity peaks at 8.5 (41 Bq/kg) and
30.5 cm core depth (94 Bq/kg) (Fig. 2). On the basis of the210Pb age model, these peaks are dated to 2000 and 1975.
The peak dated to 1975 has been reported in a previous
study and detected in several Lake Biel sediment cores,
of which the nearest is only 300 m away from our site
(Albrecht et al. 1998). This increased 137Cs activity was
caused by higher radionuclide discharges of the upstream
Muhleberg NPP due to the use of low-quality fuel rods
between 1976 and 1978 (Albrecht et al. 1998). In addition,
a small 60Co activity peak detected at 22.5 cm core depth is
dated to 1984 on the basis of our 210Pb activity age model
(Fig. 2). Albrecht et al. (1998) suggested that this peak was
related to higher wastewater discharges from the Muhle-
berg NPP documented in August of 1982. The age
difference of 1–2 years between the age model and the date
of the known nuclear events lies within the error range of
our age model (see next paragraph). Our results therefore
confirm the previous identification of increased radionu-
clide discharge by the Muhleberg NPP in 1976 (137Cs) and
1982 (60Co). However, regarding the 1982 event, our data
is not as definite as Albrecht et al. (1998, 1999) because
60Co, which was the only released radionuclide during this
event, shows at present only slightly elevated activity in
our Lake Biel record.
In the upper part of our Lake Biel sediment core, a small137Cs activity peak dated to 2000 is for the first time
revealed by this study (Fig. 1). The 60Co as well as the210Pb in excess (obtained after subtracting the 226Ra
activity to the total 210Pb activity) profiles demonstrate that
this 137Cs activity peak was not caused by other processes,
such as reworking of sediment containing Chernobyl-
linked activity or changes in sedimentation rates which
would appear in the 210Pb in excess profile. Therefore, this137Cs activity peak that is not accompanied by a coeval60Co peak can be explained by two possible causes: (1)
only 137Cs radionuclides were released to the environment,
or (2) the 137Cs was better scavenged by the minerogenic
fraction than 60Co. Indeed, only 30 to 55 % of the dis-
charged 60Co is transferred to Lake Biel sediments and the
scavenging efficiency of 60Co is higher during the winter
period than during summer, in spite of higher particle
fluxes during summer (Albrecht et al. 1999). Thus, the
found moderate 137Cs activity peak likely points to an
additional and so far undetected release of liquid radio-
nuclides from the Muhleberg NPP to the Aare River in the
year 2000 ± 2. This discharge event could coincide with
an event reported at the Muhleberg NPP on the 6th of June
1998, when an accidental opening of a steam-relief valve
led to an emergency shutdown of the reactor (Pretre 1999).
Yet, the Swiss government monitors radionuclide activity
in the air and water near the Muhleberg NPP, but registered
values for 1998 are similar to those of previous years and
lie all below 3 % of the legal limit (Pretre 1999). Similarly,
the automatic dose rate monitoring network (MADUK),
which consists of four subsidiary networks located within a
radius of 6 km of each Swiss nuclear power plant and
which has been recording since 1995 the local dose rate of
Muhleberg NPP every 10 min as a function of natural
levels of radiation, does not reveal any conspicuous values
since data was not published for most of 1998 because of
technical problems (Baur and Schug 2003).
In any case, considering that (1) Lake Biel sediments most
probably only recorded a small portion of the discharged
radionuclides (Albrecht et al. 1999), that (2) 70 % of the
drinking water of the city of Biel (57,000 inhabitants) orig-
inates from Lake Biel, and that (3) the Aare River is a main
tributary to the High Rhine River, the sedimentary profiles of
radionuclides from Lake Biel raise serious concerns about
possible large-scale contamination of drinking water and
groundwater systems by the hydrological dispersion of
radioactive materials over long distances. Indeed, NPPs are
generally built at the shores of lakes, rivers or oceans to
provide large quantities of cooling water and, similarly to the
sediment records from Lake Biel, previous studies from the
422 F. Thevenon et al.
123
Rhone River also demonstrated that radionuclides released
by the nuclear industry are dispersed through surface waters
over long distances (Martin and Thomas 1990; Provansal
et al. 2012; Ferrand et al. 2012; Albrecht et al. 1998).
Conclusion
This study highlights natural variations in terrigenous
fluxes (controlled by factors such as catchment relief,
denudation rate, river discharge volumes) and anthropo-
genic effects (building of dams and river regulation) on the
transport of suspended sediment loads from the alpine
environment to the peri-alpine foreland, i.e. to peri-alpine
lacustrine basins. The terrigenous fluxes reconstructed at
our studied sites indicate that sediment-transfer processes
at the catchment scale are significantly altered by artificial
hydropower reservoir lakes located in the upper reaches of
the catchment. Our research demonstrates that the con-
struction of dams in Switzerland significantly reduced trace
element fluxes to downstream areas over the last
*50 years. In fact, terrigenous particle fluxes have been
significantly reduced by the construction of reservoir dams
in the Swiss Alps. This result reveals the importance of
considering human-induced effects when reconstructing
past climate variations using historical discharge data and
lacustrine sedimentary archives or when estimating modern
weathering rates based on the abundance of riverine sus-
pended mineral particles. The fluxes of anthropogenically-
produced trace elements (Cu and Pb) indicate that metal
pollution significantly increases in the lower, less moun-
tainous, reaches of the Aare River by revealing the
maximum pollution between *1940 and 1970 in the sed-
iments of Lake Biel. In addition, we found that the alkyl-
lead added to gasoline was not the dominant (aquatic)
source of lead input to the studied large peri-alpine lakes.
Last but not least, the radionuclide dating of the sediment
core from Lake Biel evidences the deposition of radio-
nuclides emitted by the upstream nuclear reactor of
Muhleberg (distance 15 km) during the late 20th century.
Acknowledgments This research was funded by Swiss National
Science Foundation (SNSF) project n. 200021-121666 and a SNSF
Ambizione fellowship grant (PZ00P2 136899). Initial research on
cores from Lake Thun and Lake Brienz was funded by SNSF project
620-066113 when S.G. was at the Geological Institute of ETH Zurich
(Switzerland) under the direction of Flavio Anselmetti. We are
grateful to Christine Guido-Bruno for her help with sediment sam-
pling and laboratory analyses, to Katrina Kremer for help with MSCL
analyses, and to Adrian Gilli for access to the ETH Zurich Limno-
geology Laboratory. We thank the Federal Office for the Environment
(FOEN) in Ittingen for hydrological data. We also thank: Flavio
Anselmetti and Alois Zwyssig from Eawag for the boat, Philippe
Arpagaus from Institut Forel for equipment transport, Mathias Ruedi
and Manuel Tieche from BASPO Ipsach (Swiss Federal Sport Office)
for harbor logistics, as well as Katrina Kremer, Pauline Masset and
Aymeric Le Cotonnec from the University of Geneva for sediment
coring on Lake Biel.
Open Access This article is distributed under the terms of the
Creative Commons Attribution License which permits any use, dis-
tribution, and reproduction in any medium, provided the original
author(s) and the source are credited.
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